核心概念
Implementing coordinated load shifting and flow rate limitation strategies can significantly reduce peak flow rates in district heating systems.
摘要
This article explores strategies to reduce peak volume flow rates in district heating systems. It evaluates load shifting, return temperature limitations, and flow rate limitations. The impact of these strategies on peak flow rates, pumping power, and aggregate return temperatures is analyzed. Results show that load shifting has the most significant impact, followed by return temperature limitations. Additionally, targeting a few key consumers with these strategies can provide substantial benefits.
Abstract:
- Reduction of peak flow rate is crucial for district heating grids.
- Operational data from German district heating system evaluated.
- Load shifting, return temperature limits, and flow rate limits investigated.
Introduction:
- 4th generation district heating enables lower supply temperatures.
- Challenges arise when retrofitting existing grids for lower temperatures.
Method:
- Dataset from 18 consumer substations analyzed.
- Strategies: load shifting, return temp limits, flow rate limits explored.
Results:
- Load shifting had the greatest impact on reducing peak flow rates.
- Return temp limits provided additional benefits like reduced pumping energy.
- Flow rate limits showed diminishing returns beyond a certain limit level.
Conclusion:
- Coordinated load shifting strategy was most effective in reducing peak flow rates.
- Targeting key consumers with strategies yielded significant benefits.
统计
Three strategies for reducing the peak flow rate are investigated: A load shifting demand response strategy, an upper limitation in substation return temperatures, and an upper limitation on each substation’s volume flow rate.
引用
"Imposing up to 18% load flexibility provides an equal reduction in the peak system flow rate under the load-shifting strategy."
"The limited return temperature strategy is less efficient at curtailing the peak flow rate but provides an overall reduction of volume flow rates."